Progress toward a Si-plus architecture: epitaxially-integrable Si sub-cells for III-V/Si multijunction photovoltaics

2014 IEEE 40th Photovoltaic Specialists Conference (PVSC) Volume 2 Pub Date : 2014-06-08 DOI:10.1109/PVSC-VOL2.2014.7588253

T. Grassman, J. Carlin, S. Carnevale, Ibraheem Al Mansouri, H. Mehrvarz, S. Bremner, A. Ho-baillie, E. Garcia-Tabares, I. Rey‐Stolle, M. Green, Steven A. Ringe

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引用次数: 7

Abstract

GaP/active-Si junctions were grown by metalorganic chemical vapor deposition via a previously developed process that yields GaP-on-Si integration free of heterovalent-related defects. N-type Si emitter layers were grown on p-type (100)-oriented Si substrates, followed by the growth of n-type GaP window layers, to form fully-active sub-cell structures compatible with integration into monolithic III-V/Si multijunction solar cells. Si bulk minority carrier lifetime was found to track the epitaxial process, with initial degradation followed by full recovery. Fabricated test devices from in-situ (all-epitaxial) GaP/Si structures yielded good preliminary performance characteristics and demonstrate great promise for the epitaxial sub-cell approach. Additional test structures based on ex-situ diffusion processed solar wafers demonstrate the impact and importance of back surface field layers for such sub-cells.

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Si +结构的进展:用于III-V/Si多结光伏的外延可积Si亚电池

GaP/活性si结是通过金属有机化学气相沉积生长的，通过先前开发的工艺，可以产生无异质相关缺陷的GaP-on- si集成。在p型(100)取向Si衬底上生长n型Si发射极层，然后生长n型GaP窗口层，形成可集成到单片III-V/Si多结太阳能电池的全活性亚电池结构。发现硅体少数载流子寿命遵循外延过程，从最初的降解到完全恢复。由原位(全外延)GaP/Si结构制造的测试器件获得了良好的初步性能特征，并为外延亚电池方法展示了巨大的前景。基于非原位扩散处理太阳能晶圆的附加测试结构证明了后表面场层对此类亚电池的影响和重要性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2014 IEEE 40th Photovoltaic Specialists Conference (PVSC) Volume 2

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